A function of SmeDEF, the major quinolone resistance determinant of Stenotrophomonas maltophilia, is the colonization of plant roots

Quinolones are synthetic antibiotics, and the main cause of resistance to these antimicrobials is mutation of the genes encoding their targets. However, in contrast to the case for other organisms, such mutations have not been found in quinolone-resistant Stenotrophomonas maltophilia isolates, in wh...

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Veröffentlicht in:	Applied and environmental microbiology 2014-08, Vol.80 (15), p.4559-4565
Hauptverfasser:	García-León, Guillermo, Hernández, Alvaro, Hernando-Amado, Sara, Alavi, Peyman, Berg, Gabriele, Martínez, José Luis
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Sprache:	eng
Schlagworte:	Antimicrobial agents Bacterial Proteins - genetics Bacterial Proteins - metabolism Brassica rapa - microbiology Drug resistance Gene expression Membrane Transport Proteins - genetics Membrane Transport Proteins - metabolism Mutation Plant diseases Plant Roots - microbiology Public and Environmental Health Microbiology Quinolones - pharmacology Stenotrophomonas maltophilia Stenotrophomonas maltophilia - drug effects Stenotrophomonas maltophilia - genetics Stenotrophomonas maltophilia - growth & development Stenotrophomonas maltophilia - metabolism
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creator	García-León, Guillermo Hernández, Alvaro Hernando-Amado, Sara Alavi, Peyman Berg, Gabriele Martínez, José Luis
description	Quinolones are synthetic antibiotics, and the main cause of resistance to these antimicrobials is mutation of the genes encoding their targets. However, in contrast to the case for other organisms, such mutations have not been found in quinolone-resistant Stenotrophomonas maltophilia isolates, in which overproduction of the SmeDEF efflux pump is a major cause of quinolone resistance. SmeDEF is chromosomally encoded and highly conserved in all studied S. maltophilia strains; it is an ancient element that evolved over millions of years in this species. It thus seems unlikely that its main function would be resistance to quinolones, a family of synthetic antibiotics not present in natural environments until the last few decades. Expression of SmeDEF is tightly controlled by the transcriptional repressor SmeT. Our work shows that plant-produced flavonoids can bind to SmeT, releasing it from smeDEF and smeT operators. Antibiotics extruded by SmeDEF do not impede the binding of SmeT to DNA. The fact that plant-produced flavonoids specifically induce smeDEF expression indicates that they are bona fide effectors regulating expression of this resistance determinant. Expression of efflux pumps is usually downregulated unless their activity is needed. Since smeDEF expression is triggered by plant-produced flavonoids, we reasoned that this efflux pump may have a role in the colonization of plants by S. maltophilia. Our results showed that, indeed, deletion of smeE impairs S. maltophilia colonization of plant roots. Altogether, our results indicate that quinolone resistance is a recent function of SmeDEF and that colonization of plant roots is likely one original function of this efflux pump.
doi_str_mv	10.1128/AEM.01058-14
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However, in contrast to the case for other organisms, such mutations have not been found in quinolone-resistant Stenotrophomonas maltophilia isolates, in which overproduction of the SmeDEF efflux pump is a major cause of quinolone resistance. SmeDEF is chromosomally encoded and highly conserved in all studied S. maltophilia strains; it is an ancient element that evolved over millions of years in this species. It thus seems unlikely that its main function would be resistance to quinolones, a family of synthetic antibiotics not present in natural environments until the last few decades. Expression of SmeDEF is tightly controlled by the transcriptional repressor SmeT. Our work shows that plant-produced flavonoids can bind to SmeT, releasing it from smeDEF and smeT operators. Antibiotics extruded by SmeDEF do not impede the binding of SmeT to DNA. The fact that plant-produced flavonoids specifically induce smeDEF expression indicates that they are bona fide effectors regulating expression of this resistance determinant. Expression of efflux pumps is usually downregulated unless their activity is needed. Since smeDEF expression is triggered by plant-produced flavonoids, we reasoned that this efflux pump may have a role in the colonization of plants by S. maltophilia. Our results showed that, indeed, deletion of smeE impairs S. maltophilia colonization of plant roots. Altogether, our results indicate that quinolone resistance is a recent function of SmeDEF and that colonization of plant roots is likely one original function of this efflux pump.</description><identifier>ISSN: 0099-2240</identifier><identifier>EISSN: 1098-5336</identifier><identifier>DOI: 10.1128/AEM.01058-14</identifier><identifier>PMID: 24837376</identifier><identifier>CODEN: AEMIDF</identifier><language>eng</language><publisher>United States: American Society for Microbiology</publisher><subject>Antimicrobial agents ; Bacterial Proteins - genetics ; Bacterial Proteins - metabolism ; Brassica rapa - microbiology ; Drug resistance ; Gene expression ; Membrane Transport Proteins - genetics ; Membrane Transport Proteins - metabolism ; Mutation ; Plant diseases ; Plant Roots - microbiology ; Public and Environmental Health Microbiology ; Quinolones - pharmacology ; Stenotrophomonas maltophilia ; Stenotrophomonas maltophilia - drug effects ; Stenotrophomonas maltophilia - genetics ; Stenotrophomonas maltophilia - growth & development ; Stenotrophomonas maltophilia - metabolism</subject><ispartof>Applied and environmental microbiology, 2014-08, Vol.80 (15), p.4559-4565</ispartof><rights>Copyright American Society for Microbiology Aug 2014</rights><rights>Copyright © 2014, American Society for Microbiology. 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However, in contrast to the case for other organisms, such mutations have not been found in quinolone-resistant Stenotrophomonas maltophilia isolates, in which overproduction of the SmeDEF efflux pump is a major cause of quinolone resistance. SmeDEF is chromosomally encoded and highly conserved in all studied S. maltophilia strains; it is an ancient element that evolved over millions of years in this species. It thus seems unlikely that its main function would be resistance to quinolones, a family of synthetic antibiotics not present in natural environments until the last few decades. Expression of SmeDEF is tightly controlled by the transcriptional repressor SmeT. Our work shows that plant-produced flavonoids can bind to SmeT, releasing it from smeDEF and smeT operators. Antibiotics extruded by SmeDEF do not impede the binding of SmeT to DNA. The fact that plant-produced flavonoids specifically induce smeDEF expression indicates that they are bona fide effectors regulating expression of this resistance determinant. Expression of efflux pumps is usually downregulated unless their activity is needed. Since smeDEF expression is triggered by plant-produced flavonoids, we reasoned that this efflux pump may have a role in the colonization of plants by S. maltophilia. Our results showed that, indeed, deletion of smeE impairs S. maltophilia colonization of plant roots. 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However, in contrast to the case for other organisms, such mutations have not been found in quinolone-resistant Stenotrophomonas maltophilia isolates, in which overproduction of the SmeDEF efflux pump is a major cause of quinolone resistance. SmeDEF is chromosomally encoded and highly conserved in all studied S. maltophilia strains; it is an ancient element that evolved over millions of years in this species. It thus seems unlikely that its main function would be resistance to quinolones, a family of synthetic antibiotics not present in natural environments until the last few decades. Expression of SmeDEF is tightly controlled by the transcriptional repressor SmeT. Our work shows that plant-produced flavonoids can bind to SmeT, releasing it from smeDEF and smeT operators. Antibiotics extruded by SmeDEF do not impede the binding of SmeT to DNA. The fact that plant-produced flavonoids specifically induce smeDEF expression indicates that they are bona fide effectors regulating expression of this resistance determinant. Expression of efflux pumps is usually downregulated unless their activity is needed. Since smeDEF expression is triggered by plant-produced flavonoids, we reasoned that this efflux pump may have a role in the colonization of plants by S. maltophilia. Our results showed that, indeed, deletion of smeE impairs S. maltophilia colonization of plant roots. Altogether, our results indicate that quinolone resistance is a recent function of SmeDEF and that colonization of plant roots is likely one original function of this efflux pump.</abstract><cop>United States</cop><pub>American Society for Microbiology</pub><pmid>24837376</pmid><doi>10.1128/AEM.01058-14</doi><tpages>7</tpages><oa>free_for_read</oa></addata></record>
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subjects	Antimicrobial agents Bacterial Proteins - genetics Bacterial Proteins - metabolism Brassica rapa - microbiology Drug resistance Gene expression Membrane Transport Proteins - genetics Membrane Transport Proteins - metabolism Mutation Plant diseases Plant Roots - microbiology Public and Environmental Health Microbiology Quinolones - pharmacology Stenotrophomonas maltophilia Stenotrophomonas maltophilia - drug effects Stenotrophomonas maltophilia - genetics Stenotrophomonas maltophilia - growth & development Stenotrophomonas maltophilia - metabolism
title	A function of SmeDEF, the major quinolone resistance determinant of Stenotrophomonas maltophilia, is the colonization of plant roots
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